费氏丙酸杆菌中的有氧电子传递。氰化物的影响。

Aerobic electron transport in Propionibacterium shermanii. Effects of cyanide.

作者信息

Pritchard G G, Asmundson R V

出版信息

Arch Microbiol. 1980 Jun;126(2):167-73. doi: 10.1007/BF00511223.

DOI:10.1007/BF00511223

Abstract

Cyanide inhibited D- and L-lactate and NADH oxidase activities of membrane particles from Propionibacterium shermanii but only at relatively high concentrations. Inhibition occurred at two different sites in the electron transport pathway. One site, with a half-maximal inhibition concentration (I0.5) of 2 to 3 mM KCN, is located at the terminal oxidase involved in cytochrome b oxidation; the evidence is consistent with cytochrome d being the major oxidase involved. At high concentrations, cyanide inhibited reduction of cytochrome b by D-lactate (I0.5 value 20-25 mM cyanide). A proportion of the oxygen-uptake remained uninhibited even by 100 mM cyanide; this proportion was about 80% for succinate, 30% for L-lactate, 15% for D-lactate and 10% for NADH. The oxygen uptake per mol of substrate oxidised increased with increasing cyanide concentration and was accompanied by the formation of hydrogen peroxide as a product of a cyanide-insensitive oxidase system.

摘要

氰化物可抑制谢氏丙酸杆菌膜颗粒的D-和L-乳酸以及NADH氧化酶活性，但仅在相对较高的浓度下才会出现这种抑制作用。抑制作用发生在电子传递途径中的两个不同位点。一个位点的半数最大抑制浓度（I0.5）为2至3 mM KCN，位于参与细胞色素b氧化的末端氧化酶处；证据表明细胞色素d是主要参与的氧化酶。在高浓度下，氰化物抑制D-乳酸对细胞色素b的还原作用（I0.5值为20 - 25 mM氰化物）。即使在100 mM氰化物存在的情况下，仍有一部分氧摄取不受抑制；对于琥珀酸，这一比例约为80%，对于L-乳酸为30%，对于D-乳酸为15%，对于NADH为10%。每摩尔被氧化底物的氧摄取量随着氰化物浓度的增加而增加，并且伴随着作为氰化物不敏感氧化酶系统产物的过氧化氢的形成。

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